Sometimes associativity can be used to loose data dependencies and I was curious how much it can help. I was rather surprised to find out that I can nearly get a speed-up **factor of 4** by manually unrolling a trivial loop, both in Java (build 1.7.0_51-b13) and in C (gcc 4.4.3).

So either I'm doing something pretty stupid or the compilers ignore a powerful tool. I started with

```
int a = 0;
for (int i=0; i<N; ++i) a = M1 * a + t[i];
```

which computes something close to `String.hashCode()`

(set `M1=31`

and use a `char[]`

). The computation is pretty trivial and for `t.length=1000`

takes about 1.2 microsecond on my i5-2400 @ 3.10GHz (both in Java and C).

Observe that each two steps `a`

gets multiplied by `M2 = M1*M1`

and added something. This leads to this piece of code

```
int a = 0;
for (int i=0; i<N; i+=2) {
a = M2 * a + (M1 * t[i] + t[i+1]); // <-- note the parentheses!
}
if (i < len) a = M1 * a + t[i]; // Handle odd length.
```

This is exactly twice as fast as the first snippet. Strangely, leaving out the parentheses eats 20% of the speed-up. Funnily enough, this can be repeated and a factor of 3.8 can be achieved.

Unlike java, `gcc -O3`

chooses not to unroll the loop. It's wise choice since it wouldn't help anyway (as `-funroll-all-loops`

shows).

So my question^{1} is: What prevents such an optimization?

^{Googling didn't work, I got "associative arrays" and "associative operators" only.}

## Update

I polished up my benchmark a little bit and can provide some results now. There's no speedup beyond unrolling 4 times, probably because of multiplication and addition together taking 4 cycles.

## Update 2

As Java already unrolls the loop, all the hard work is done. What we get is something like

```
...pre-loop
for (int i=0; i<N; i+=2) {
a2 = M1 * a + t[i];
a = M1 * a2 + t[i+1];
}
...post-loop
```

where the interesting part can be rewritten like

```
a = M1 * ((M1 * a) + t[i]) + t[i+1]; // latency 2mul + 2add
```

This reveals that there are 2 multiplications and 2 additions, all of them to be performed sequentially, thus needing 8 cycles on a modern x86 CPU. All we need now is some primary school math (working for `int`

s even in case of overflow or whatever, but not applicable to floating point).

```
a = ((M1 * (M1 * a)) + (M1 * t[i])) + t[i+1]; // latency 2mul + 2add
```

So far we gained nothing, but it allows us to fold the constants

```
a = ((M2 * a) + (M1 * t[i])) + t[i+1]; // latency 1mul + 2add
```

and gain even more by regrouping the sum

```
a = (M2 * a) + ((M1 * t[i]) + t[i+1]); // latency 1mul + 1add
```

`{`

and`}`

of the`for`

loop, this is quite impossible: it compiles to the same code either way; which casts doubt on your testing methodology. If you mean the`(`

and`)`

in the expression inside the loop, omitting them changes the meaning of the expression, so you are comparing apples and oranges. – user207421 Feb 13 '14 at 5:17`x + (y + z)`

with`x = M2 * a`

,`y = M1 * t[i]`

, and`z = t[i+1]`

(unless I'm completely blind). The problem is that it lengthens the dependency chain containing`a`

and the compiler doesn't care. – maaartinus Feb 13 '14 at 5:283more comments